Identification and characterization of the Bacillus subtilis spore germination protein GerY.

IF 2.7 3区 生物学 Q3 MICROBIOLOGY
Fernando H Ramírez-Guadiana, Anna P Brogan, David Z Rudner
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Abstract

In response to starvation, endospore-forming bacteria differentiate into stress-resistant spores that can remain dormant for years yet rapidly germinate and resume growth when nutrients become available. To identify uncharacterized factors involved in the exit from dormancy, we performed a transposon-sequencing screen taking advantage of the loss of spore heat resistance that accompanies germination. We reasoned that transposon insertions that impair but do not block germination will lose resistance more slowly than wild type after exposure to nutrients and will therefore survive heat treatment. Using this approach, we identified most of the known germination genes and several new ones. We report an initial characterization of 15 of these genes and a more detailed analysis of one (ymaF). Spores lacking ymaF (renamed gerY) are impaired in germination in response to both L-alanine and L-asparagine, D-glucose, D-fructose, and K+. GerY is a soluble protein synthesized under σE control in the mother cell. A YFP-GerY fusion localizes around the developing and mature spore in a manner that depends on CotE and SafA, indicating that it is a component of the spore coat. Coat proteins encoded by the gerP operon and gerT are also required for efficient germination, and we show that spores lacking two or all three of these loci have more severe defects in the exit from dormancy. Our data are consistent with a model in which GerY, GerT, and the GerP proteins are required for efficient transit of nutrients through the coat to access the germination receptors, but each acts independently in this process.

Importance: Pathogens in the orders Bacillales and Clostridiales resist sterilization by differentiating into stress-resistant spores. Spores are metabolically inactive and can remain dormant for decades, yet upon exposure to nutrients, they rapidly resume growth, causing food spoilage, food-borne illness, or life-threatening disease. The exit from dormancy, called germination, is a key target in combating these important pathogens. Here, we report a high-throughput genetic screen using transposon sequencing to identify novel germination factors that ensure the efficient exit from dormancy. We identify several new factors and characterize one in greater detail. This factor, renamed GerY, is part of the proteinaceous coat that encapsulates the dormant spore. Our data suggest that GerY enables efficient transit of nutrients through the coat to trigger germination.

枯草芽孢杆菌孢子萌发蛋白 GerY 的鉴定和表征。
为了应对饥饿,内孢子形成细菌会分化出抗压孢子,这些孢子可以保持休眠状态数年之久,但在获得养分后又能迅速发芽并恢复生长。为了确定参与退出休眠的未表征因子,我们利用孢子发芽时丧失的耐热性进行了转座子测序筛选。我们推断,转座子插入会损害但不会阻止萌发,在暴露于营养物质后,其抗性的丧失速度会比野生型慢,因此能在热处理中存活下来。利用这种方法,我们确定了大多数已知的萌发基因和几个新基因。我们报告了其中 15 个基因的初步特征,并对其中一个基因(ymaF)进行了更详细的分析。缺乏 ymaF(改名为 gerY)的孢子对 L-丙氨酸、L-天冬酰胺、D-葡萄糖、D-果糖和 K+ 的萌发均有障碍。GerY 是一种可溶性蛋白质,在母细胞中受 σE 控制合成。YFP-GerY 融合体以依赖 CotE 和 SafA 的方式定位于发育中和成熟的孢子周围,表明它是孢子衣壳的一个组成部分。由 gerP 操作子和 gerT 编码的包被蛋白也是有效萌发所必需的,我们的研究表明,缺乏其中两个或全部三个基因座的孢子在脱离休眠时会出现更严重的缺陷。我们的数据与以下模型一致:GerY、GerT 和 GerP 蛋白是营养物质有效通过外皮到达萌发受体的必要条件,但它们在这一过程中各自独立发挥作用:重要意义:芽孢杆菌目和梭菌目病原体通过分化为抗压孢子来抵抗灭菌。孢子代谢不活跃,可保持休眠状态数十年之久,但一旦接触到营养物质,就会迅速恢复生长,导致食品腐败、食源性疾病或危及生命的疾病。摆脱休眠的过程被称为萌芽,是抗击这些重要病原体的关键目标。在这里,我们报告了一项利用转座子测序技术进行的高通量遗传筛选,以鉴定确保高效脱离休眠的新型萌发因子。我们发现了几个新因子,并对其中一个因子进行了更详细的描述。该因子被重新命名为 GerY,是包裹休眠孢子的蛋白衣壳的一部分。我们的数据表明,GerY 能使营养物质有效地通过外衣,从而触发萌发。
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来源期刊
Journal of Bacteriology
Journal of Bacteriology 生物-微生物学
CiteScore
6.10
自引率
9.40%
发文量
324
审稿时长
1.3 months
期刊介绍: The Journal of Bacteriology (JB) publishes research articles that probe fundamental processes in bacteria, archaea and their viruses, and the molecular mechanisms by which they interact with each other and with their hosts and their environments.
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